Classifications

• • G—PHYSICS
  • G08—SIGNALLING
  • G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
  • G08B25/00—Alarm systems in which the location of the alarm condition is signalled to a central station, e.g. fire or police telegraphic systems
  • G08B25/01—Alarm systems in which the location of the alarm condition is signalled to a central station, e.g. fire or police telegraphic systems characterised by the transmission medium
  • G08B25/10—Alarm systems in which the location of the alarm condition is signalled to a central station, e.g. fire or police telegraphic systems characterised by the transmission medium using wireless transmission systems
• • G—PHYSICS
  • G08—SIGNALLING
  • G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
  • G08B17/00—Fire alarms; Alarms responsive to explosion
• • G—PHYSICS
  • G08—SIGNALLING
  • G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
  • G08B25/00—Alarm systems in which the location of the alarm condition is signalled to a central station, e.g. fire or police telegraphic systems
  • G08B25/007—Details of data content structure of message packets; data protocols
• • Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
  • Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
  • Y02D—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
  • Y02D30/00—Reducing energy consumption in communication networks
  • Y02D30/70—Reducing energy consumption in communication networks in wireless communication networks

Definitions

• the present invention is related to a radio communication system between battery-powered terminals. BACKGROUND ART
• each detecting terminal is configured to have a warning device and also a receiver for receiving the fire detection data from any one of the other detecting terminals through radio communication so that every detecting terminal can issue an alarm when any one of the detecting terminals detect the fire occurrence.
• radio communication system is likely to suffer from various environmental noises including a conflicting radio signal utilized in other radio communication system which have to be distinguished from the fire detection data on the side of the receiver.
• the noise can be distinguished only after processing the received data or signal at an expense of corresponding power on the side of the receiving terminal.
• the conflicting radio signal can be designated only after receiving at least a unique word contained in the signal, which necessitates undue consumption of the battery before completing to read the unique word.
• the system wastes the battery each time such noise is received, and therefore shortens its operation life. In this sense, the prior art system is not sufficient for reducing battery consumption while the system is idling or waiting for receiving valid data.
• the radio communication system in accordance with the present invention includes a first radio terminal (10A) and a second radio terminal (10B) linked for radio communication with each other.
• the first radio terminal (10A) includes a first transmitter (40A) configured to transmit a first data indicative of a specific event.
• the second radio terminal (40B) includes a second battery (14B) energizing the second radio terminal, a second receiver (20B) for receiving the first data from the first radio terminal, a data analyzer (26B) configured to analyze the first data and generate information designated by the first data, an information provider (50B) configured to output the information, a second signal intensity detector configured to provide a receiving signal strength indication (RSSI) and to deactivate the second receiver when the RSSI is lower than a predetermined threshold.
• the first radio terminal (10A) is specifically designed to include a first bit interpolator (32A) which is configured to insert a check bit pattern at a predetermined cycle into one frame of the first data to make up a first bit-interpolated data to be transmitted to the second radio terminal.
• the check bit pattern is defined to be a bit series of "0" alternating with "1".
• the second radio terminal (10B) is designed to include a second power controller (60B) which is configured to intermittently activate the second receiver (20B) at predetermined intervals in order to receive the first bit-interpolated data from the first transmitter.
• the second radio terminal (10B) also include a second check bit detector (24B) which is configured to find whether the check bit pattern is detected from within the first bit interpolated data.
• the second check bit detector is configured to issue a stop signal immediately upon occurrence of that the check bit pattern fails to appear within a predetermined second detection time period shorter than one frame length of the first data.
• the second power controller of the second radio terminal is configured to terminate a current receiving operation of the second receiver and associated components for processing the receiving data, in response to the stop signal.
• the second receiver can determine whether or not the receiving data is valid before completing reading the one frame length of the data, and stop current receiving operation immediately upon finding that the receiving data is invalid or lacks the check bit pattern. Accordingly, the second receiver can eliminate wasteful power consuming operation caused by noises, and can reduce battery consumption, in addition to the intermittent receiving operation. Therefore, the system can have a prolonged operation life even in a situation where noises of considerable level are expected.
• the second power controller (60B) may be configured to terminate a current receiving operation of the second receiver (20B) when the receiving signal strength indication (RSS) is lower than the predetermined threshold.
• the second check bit detector (24B) may be configured to be enabled when the second signal intensity detector (22B) provides the RSS not lower than the above threshold, and to allow the second receiver (20B) to continue the current receiving operation when the check bit pattern appears within the second time period which is not shorter than the predetermined cycle.
• the second power controller (60B) may be configured to extend the second detection time period to a second uw detection time period for detection of a unique word contained in the first data only when the check bit pattern appears at least once within the second detection time period, and to extend the second detection time period further to a second data detection time period for completely reading the first data only when the unique word is detected within the second uw detection time period. In this manner, the receiving terminal is enabled to continue receiving the first data so long as the first data include the valid unique word specific to the system.
• the second power controller (60B) is configured to terminate the second uw detection time period immediately when the check bit pattern first fails to appear at the predetermined cycle within the second uw detection time period, and to terminate the second data detection time period immediately when the check bit pattern fails first to appear at the predetermined interval within the second data detection time period.
• the system can regard the receiving data as invalid as soon as the check bit pattern fails to appear at the predetermined interval, and terminate the current receiving operation at an early stage of receiving the invalid data, thereby reducing the power consumption.
• the check bit pattern is preferred to have a length of one byte, and the first check bit interpolator (32A) is configured to insert the check bit pattern in such a manner that the check bit pattern alternative with one byte fraction of the first data.
• the second check bit detector is configured to have the second detection time period of three byte.
• the first data is generally structured to have the unique word preceding data fields and following a preamble of a synchronous bit series for synchronous data reception at the second receiver.
• the first check bit interpolator is configured to insert the check bit pattern into a data stream beginning from the unique word
• the second power controller (60B) is configured to extend the second detection time to the second uw detection time period having a length equal to one frame length of the first data or more for detection of the unique word when the check bit pattern appears in the second detection time period.
• the second power controller is configured to extend the second detection time further to the second data detection time period for reading the first data when the unique word is detected within the second uw detection time period.
• the second power controller is configured to issue the stop signal when the check bit pattern fails first to appear at the predetermined cycle within the second uw detection time period or second data detection time period.
• the first check bit interpolator may be configured to insert the check bit pattern into the data stream after the unique word.
• the second power controller (60B) is configured to extend the second detection time to the second uw detection time period for detection of the unique word only when the check bit pattern appears in the second detection time, and further to the second data detection time period only when the unique word is detected in the second uw detection time period.
• the second power controller is configured to issue the stop signal when the check bit pattern fails first to appear at the predetermined cycle within the second data detection time period.
• the second receiver can successfully find out the true unique word from within the received data, without requiring the system to employ any other sophisticated technique of bit-modifying the unique word to make the unique word more distinctive.
• the first data is prepared by a non return-to-zero coding such that the second check bit detector can also function to achieve a bit synchronization for receiving the first data through the second receiver in response to the preamble.
• the second check bit detector can alone make the detection of the check bit pattern as well as the bit synchronization, contributing to simply the system arrangement.
• the second radio terminal is configured to transmit a second data to the first terminal, and therefore include a second bit interpolator (32B) configured to insert the check bit pattern at the predetermined cycle into one frame of the second data to make up a second bit interpolated data to be transmitted to the first radio terminal.
• a second bit interpolator 32B
• the first radio terminal is configured to additionally include a first battery (14A) energizing the first radio terminal, a first signal intensity detector (22A) configured to provide a receiving signal strength indication (RSSI) and to deactivate the first receiver when the RSSI is lower than a predetermined threshold, a first power controller (60A) configured to intermittently activate the first receiver (20A) at predetermined intervals in order to receive the second bit interpolated data, and a first check bit detector (24A) configured to detect the check bit pattern from within the second bit interpolated data from the second radio transmitter.
• a first battery 14A
• a first signal intensity detector 22A
• RSSI receiving signal strength indication
• a first power controller 60A
• a first check bit detector configured to detect the check bit pattern from within the second bit interpolated data from the second radio transmitter.
• the first check bit detector is configured to issue a stop signal immediately upon occurrence of that the check bit pattern fails to appear at the predetermined cycle within a first detection time period shorter than one frame length of the second data.
• the first power controller (60A) is configured to terminate a current receiving operation of the first receiver (20A) in response to the stop signal from the first check bit detector.
• the first detection time period on the side of the first radio terminal can be defined to be similar to that of the second radio terminal, as discussed in the above.
• the second data may be prepared by the non return-to-zero coding such that the first check bit detector can alone make the detection of the check bit pattern as well as the bit synchronization.
• FIG. 1 is a schematic view illustrating a fire alarm system utilizing a radio communication system in accordance with the present invention
• FIG. 2 is a block diagram of a first radio terminal (fire detecting terminal) utilized in the above system;
• FIG. 3 is a block diagram of a second radio terminal (master station) utilized in combination with the first radio terminal in the above system;
• FIG 4 is a schematic view of a data structure of a data transmitted between the first and second radio terminals
• FIG. 5 is a time chart illustrating a data receiving operation of the above system
• FIG. 6 is a flow chart illustrating the data receiving operation of the above system
• FIG. 7 is a time chart illustrating a fire detecting operation of the above fire alarm system.
• FIG. 8 is a schematic view of a data structure of the data transmitted between the first and second radio terminals in accordance with a modification of the above embodiment.
• the fire alarm system includes a master station 10B installed in one particular room in premises, and a plurality of fire detecting terminals 10A installed in other rooms.
• the fire detection terminal 10A is configured to detect a fire occurrence and transmit a fire detecting message upon the fire occurrence to the other fire detecting terminals 10A as well as the master station 10B in order to give a fire alarm at each of the fire detecting terminals 10A and the master station 10B.
• the fire detecting message is generated on the fire detecting terminal and is transmitted by way of a radio communication proposed by the present invention.
• the master station 10B and the fire detecting terminal 10A are realized by one common module powered by an incorporated battery 14B (14A), and are designated to give respective functions as the master station and the fire detecting terminal by a master/slave selector.
• FIGS. 2 and 3 show a configuration of the fire alarm system as one application of the radio communication system of the present invention which is defined in the claims and described in the disclosure of the invention to have a first radio terminal and a second radio terminal linked for radio communication with each other.
• the fire detecting terminals 10A are linked to communicate with the master station 1OB as well as to communicate with each other, the following description is based upon a conception that the first radio terminal is interpreted as a transmitting terminal which may be the fire detecting terminal 10A or the master station 10B in the following description, and the second radio terminal is interpreted as a receiving terminal which may be the fire detecting terminal 10A or the master station 10B.
• first radio terminal 10A, 10B components belonging to the first radio terminal 10A, 10B are mentioned in the claims and the disclosure of the invention to be preceded by a modifier term of "first”, while components belonging to the second radio terminal 10A, 10B are mentioned to be preceded by a modifier term of "second”, while such modifier terms are omitted from the drawings and the following description only for the sake of simplicity.
• some data transmitted between the first terminal and the second terminal may be hereinafter referred to as a fire detecting message or a wake-up message.
• FIG. 4 shows a data structure of the message or data transmitted between the first and second terminals.
• the data is basically structured to have a unique word of 2 bytes following a preamble containing a synchronous bit series of 8 bytes, a destination address of 6 bytes, a source address of 6 bytes, a message content of 100 bytes, and a CRC (cyclic redundancy check) of 2 bytes.
• a check bit pattern of "01010101" is inserted at a predetermined cycle, i.e., one byte length cycle, into the data so as to give a bit interpolated data in which the check bit pattern starts from the beginning of the data frame, i.e., the unique word and ending at the CRC, and alternate with one byte fraction of the data.
• the system can determine that the receiving data is simply the noise or the data not intended to the present radio transmission system and operates in order to save a power, as will discussed hereinafter in detail.
• the fire detecting terminal 10A is designed as the transmitting terminal to include a fire sensor 12A configured to detect a fire occurrence, an information generator 3OA which generates the fire detection message upon detection of the fire occurrence, a check bit interpolator 32A configured to insert the check bit pattern of "01010101" into one frame of the data or message to give the bit interpolated data or the message of FIG. 4, and a transmitter 40A configured to transmit the bit interpolated fire detection message.
• the fire detecting terminal 10A is designed as also the receiving terminal to include a receiver 2OA, a signal intensity detector 22A configured to provide a receiving signal strength indication (RSSI) of the received data, a check bit detector 24A configured to detect whether the check bit pattern appears in the received data, a data analyzer 26A configured to analyze the data and generate information designated by the data, and an information provider 5OA configured to issue the information or fire alarm in the form of a voice.
• the signal intensity detector 22A is made active with or without the check bit detector 24A and the data analyzer 26A when the receiver 2OA receives any signal including the valid data or environmental noises of significant level, and consume the battery power.
• the signal intensity detector 22A defines a signal processing section by itself or in combination with the check bit detector 24A and the data analyzer 26A. When the signal processing section is activated together with the receiver, the terminal 10A consumes a considerable battery power.
• the master station 10B is also configured as the receiving terminal to include a receiver 2OB, a signal intensity detector 22B, a check bit interpolator 32B, and an information provider 5OB which are all of the same configuration to corresponding ones of the fire detecting terminal 10A.
• the master station 10B is designed as the transmitting terminal to include a fire sensor 12B, an information generator 3OB, a check bit interpolator 32B, and a transmitter 40B, all of which are of the same configuration to corresponding ones of the fire detecting terminal 10A.
• the signal intensity detector 22B is made active with or without the check bit detector 24B and the data analyzer 26B when the receiver 2OB receives any signal including the valid data or environmental noises, and consume the battery power.
• the signal intensity detector 22B defines a signal processing section by itself or in combination with the check bit detector 24B and the data analyzer 26B.
• the master station 10B consumes a considerable battery power when the receiver is activated together with the signal processing section.
• the fire detecting terminal 10A and the master station 10B include respective timers 62A and 62B, and power controllers 6OA and 6OB.
• the power controller 6OA (60B) is configured to intermittently activate the corresponding receiver 2OA (20B) only for a limited reception period (Rp) of several tens of milliseconds, which repeat at predetermined intervals of about 5 to 10 seconds given by a timing signal from the corresponding timer 62A (62B) with the reception period alternating with a rest period.
• Rp reception period
• the receiver is kept in an idling mode only in the reception period with a minimum consumption of the battery power so as to be ready for receiving signal or data, while it is kept halted for the rest period without consuming the battery power.
• the receiver becomes fully activated to start reading the signal or data with considerable battery consumption.
• the fire alarm system is configured to have an intermittent reception mode of activating each of the fire detecting terminals 10A and master station 10B intermittently to be ready for receiving the data or message, and a constant reception mode of constantly keeping the fire detecting terminal and the master station ready for receiving the data.
• the power controller is configured to select the intermittent reception mode until receiving the fire detection message or the wake-up message whichever comes earlier, and select the constant operation reception mode thereafter to receive the fire information message which establishes a multiple synchronous TDMA communication among the terminals and the master station.
• the system is configured to transmit a series of the data or message until the constant reception mode is available.
• the fire detection message or the wake-up message is transmitted as a time series successive data.
• it is first checked at each of the reception period (Rp) whether or not the RSSI of the received signal is greater than the threshold.
• the power controller 6OB 60A responds to set a detection time period (DT) of a 3 bytes length from the start of the reception period (Rp) for checking whether or not the incoming message includes at least one check bit pattern "01010101".
• the power controller 6OB (60A) responds to immediately terminate the detection period (DT) to deactivate the receiver 2OB (20A) and the associated components until the next reception period (Rp).
• the power controller 6OB (60A) regards the receiving message is the noise or message not intended to the present system, and terminates the extended time period to terminate the instant receiving operation.
• the power controller 6OB activates the receiver 2OB (20A) to be ready fro receiving the data.
• a step follows to determine whether RSSI of the receiving signal exceeds a predetermined threshold at the signal intensity detector 22B (22A). When RSSI is found greater than the threshold, the detection time period (DT) corresponding to three bytes length is set to start receiving the message. . Then, the check bit detector 24B (24A) checks whether the check bit pattern "01010101" appears at least once or twice within the detection time period (DT).
• the power controller 6OB (60A) provides a stop signal for terminating the detection period and therefore the current receiving operation to save the battery power.
• the detection time period is further extended to the data detection time period (Ex2) to complete reading the one frame message within a detection period of one frame length or more starting from the unique word. If the check bit pattern fails to appear at the predetermined cycle, i.e., 2 bytes length cycle during the uw or data detection time period, the power controller acknowledges that the receiving data is invalid and provides the stop signal for immediately terminating the current receiving operation to save the battery power as well.
• the receiving data is continuously checked. If the check bit detector 24B (24A) detects no further data within the data detection time period, the power controller provides the stop signal for terminating the instant receiving operation until next reception period.
• the data analyzer 26B (26A) checks whether the destination address in the receiving data designates own address of the transmitting terminal or those of the other receiving terminals. If the address is determined for its own or for multicasting to the other receiving terminals, the sequence goes to a step of checking whether one frame data reception is completed, and to check whether the CRC is verified.
• the data analyzer 26B (26A) requests the power controller 6OB (60A) to continue activate the receiver 2OB (20A) to read the remaining data 1 byte by 1 byte. If the CRC fails, the data analyzer 26B (26A) issues another stop signal to the power controller for immediately terminating the instant receiving operation. If the CRC is verified, the data analyzer 26B (26A) acknowledges the completion of the valid receiving data, stops the receiving operation, and starts a data processing for causing the information provider 5OB (50A) to issue the information as instructed by the receiving data.
• the data reception in the intermitted reception mode is terminated for saving the power as soon as one of the following conditions comes first:
• check bit detector 24B 24A can be shared to make the function of achieving the bit synchronization for receiving the data in response to the preamble, and to make the function of detecting the check bit pattern.
• the system have the detection time period longer than 3 bytes length, for example, 4 bytes to 10 bytes.
• the check bit detector 26B (26A) can be designed to check the number of the appearances of the check bit pattern in each detection time period and to provide the stop signal when the number of the appearance is smaller than a predetermined reference number.
• the system of the present invention may have a configuration in which the check bit pattern is inserted in the data stream after the unique word in order to make the unique word sufficiently distinctive with a simple coding design.
• the present invention includes a modification of the above embodiment which is similar to the above embodiment except that the unique word is structured to include two bytes series data.
• the unique word having the 2 bytes series data not interrupted by check bit pattern "01010101" is designed to make the unique word more distinctive at the two byte series data than corresponding data fractions in the remaining message.
• the initial detection time period (DT) is set to have a 4 byte length for checking whether one or two the check bit patterns appear tin the initial detection time period.
• the power controller After confirming the presence of the check bit pattern in the initial detection time period, the power controller extends the detection time period to the uw detection time period of one frame length or more and further to the data detection time period in much the same manner as in the above embodiment to check whether the check bit pattern appears at the predetermined cycle of 2 bytes in both of the uw detection time period and the data detection time period.
• the details of the fire alarm system are now explained with reference to FIGS. 2, 3 and 7.
• the common module for the fire detecting terminal 10A and the master station 10B is equipped with the master/slave selector 7OA (70B) for selectively designating the common module as the fire detecting terminal 10A and the master station 10B, and also with a set-up memory 72A (72B) configured to store addresses of associated terminals in addition to the designated role for multicast communication
• transmission controller 42A (42B) which fetches the addresses from the set-up memory 32A (32B) each time the fire detecting terminal or the master station transmits the data to include the destined addresses in the transmitting data prepared at the information generator 3OA (30B).
• the common module includes a demand generator 8OA (80B) which is configured to generate a warning stop demand in response to a user's entry by use an interface such as a button or keypad.
• the demand is fed to the information generator 3OA to be included in the transmitting data destined to the master station 10B to be processed thereat in order to stop the fire warning from the information providers 5OB and 5OA of the master station 10B as well as the fire detecting terminals 10A.
• each of the fire detecting terminals FT1 to FT4 and the master station MS are normally kept respectively in the intermittent reception mode where the individual power controllers 6OA (60B) makes the corresponding receivers 2OA (20B) ready for receiving signal in the reception period (Rp) alternating with the rest period, i.e., setting the receivers in an idling condition at regular intervals (T) of about 5 to 10 seconds.
• any one of the fire detecting terminals 10A first detects the fire condition, for example, the fire detecting terminal of FT1 detects the fire condition at a time t ⁇ , the terminal FT1 responds to generate the data of fire detection message, concurrently with issuing the fire alarm from its own information provider.
• the fire detection message is destined to all the other fire detecting terminals FT2, FT3, FT4 and the master station MS, and is transmitted repeatedly in transmission period Tp alternating with reception period Rp.
• the fire detection message is successfully received at the other fire detecting terminals FT2, FT3 and the master station MS each having one of its intermittent reception periods coincident with any one of the transmission periods Tp.
• the fire detecting terminals FT2 and FT3 receive the fire detection message respectively at times t1 and t2, and the master station MS receive the message at time t3.
• the terminal FT4 fails to receive the message when it spaced from the transmitting terminal FT1 by a distance greater than a maximum communication distance, or when the terminal FT4 receives a coincidental noise interfering with the message from terminal FT1 , or even when any one of its reception periods Rp of the terminal FT4 is not coincident with any of the transmission periods Tp of the terminal FT1.
• the terminals FT2 and FT3 Upon receiving the fire detection message, the terminals FT2 and FT3 respond to issue the fire alarm from their own information providers 5OA (50B), and are respectively switched into the constant operation mode in which the terminals are ready for the TDMA communication with the master station MS to receive and transmit further message and reply.
• the master station MS when receiving the fire detection message at time t3, is switched into a wake-up mode of generating and transmitting a wake-up message to all the terminals FT1 to FT4.
• the wake-up message is intended to wake-up any remaining terminal FT4 which has not been switched into the constant operation mode by the fire detection message from the terminal FT1 , and is repeated for a limited number of times to successfully switch the terminal FT4 into the constant operation mode at time t5 and to cause the terminal FT4 to issue the fire alarm. It should be noted in this connection that even when each of the fire detecting terminals FT1 to FT4 is located within the maximum communication distance for successful radio communication with the master station MS, there may be a situation that one of the fire detecting terminals FT1 to FT4 is located far beyond the maximum communication distance from one or more particular fire detecting terminals.
• the terminal FT4 when the terminal FT4 is spaced further away from the detecting terminal FT1 issuing the fire detection message than from the master station, the terminal FT4 fails to receive the fire detection message. However, as the terminal FT4 is within the maximum communication distance from the master station MS, the terminal FT4 can successfully receive the wake-up message from the master station MS and be therefore switched into the constant reception mode. Further, if the terminal FT4 should fail to be woke up by the fire detecting message from the terminal FT1 due to the interference with the noise or misregistration between the reception period Rp of FT4 and the transmission period Tp of FT1 , the terminal FT4 can be successfully woke up by the wake-up message repeatedly transmitted from the master station MS.
• the terminal FT1 Upon receiving the wake-up message at time t4 , the terminal FT1 is caused to stop transmitting the fire detection message and come into the constant reception mode to be ready for the TDMA communication with the master station MS. After transmitting the wake-up message for the predetermined number of times, the master station MS comes also into the constant reception mode to be ready for the TDMA communication with all the terminals FT1 to FT4. Subsequently at time t6, the master station MS generates and transmits a fire information message which includes a statement of defining a series of timeslots TS assigned to each of the terminals FT1 to FT4, and includes a request for acknowledgment from each of the terminals FT1 to FT4 through the individual timeslots.
• the terminals FT1 to FT4 are held in constant communication with the master station for exchanging information and instructions for implementation of the fire alarm system. It is noted in this connection that the above mode switching is effected by the power controller 6OA (60B) in combination with the data analyzer 26A (26B) in the respective terminal and the master station.
• the terminal and the master station are each functioning as the transmitting and receiving terminal, and specifically the fire detecting terminals function to transmit and receive the fire detection message with each other, in addition to communication with the master station.
• the claims and the disclosure of the invention describe the claimed elements with reference numerals only with reference to one particular data transmission of the fire detection message from the terminal to the master station, although the such data transmission may be made between the fire detecting terminals or the other data transmission of the wake-up message is made from the master station to the terminals.

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• Business, Economics & Management (AREA)
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• Physics & Mathematics (AREA)
• General Physics & Mathematics (AREA)
• Engineering & Computer Science (AREA)
• Computer Networks & Wireless Communication (AREA)
• Mobile Radio Communication Systems (AREA)
• Fire Alarms (AREA)
• Alarm Systems (AREA)
• Circuits Of Receivers In General (AREA)
• Radio Relay Systems (AREA)

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• 2008
  • 2008-01-16 DE DE602008003542T patent/DE602008003542D1/de active Active
  • 2008-01-16 ES ES08703836T patent/ES2353825T3/es active Active
  • 2008-01-16 US US12/523,485 patent/US8401059B2/en not_active Expired - Fee Related
  • 2008-01-16 WO PCT/JP2008/051009 patent/WO2008088078A1/en active Application Filing
  • 2008-01-16 JP JP2009526829A patent/JP4966379B2/ja active Active
  • 2008-01-16 AT AT08703836T patent/ATE488827T1/de not_active IP Right Cessation
  • 2008-01-16 EP EP08703836A patent/EP2126868B1/de active Active

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